Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 6 5 4 3 2 Mg(s) + C l 2 (g) MgC l 2 (s) Mg(g) + C l 2 (g) Mg(g) + 2C l (g) Mg 2+ (g) + 2C l – (g) 7 Mg + (g) + 2C l (g) Mg 2+ (g) + 2C l (g) Enthalpy.

Published byTheodore Moore Modified over 8 years ago

Similar presentations

Presentation on theme: "1 6 5 4 3 2 Mg(s) + C l 2 (g) MgC l 2 (s) Mg(g) + C l 2 (g) Mg(g) + 2C l (g) Mg 2+ (g) + 2C l – (g) 7 Mg + (g) + 2C l (g) Mg 2+ (g) + 2C l (g) Enthalpy."— Presentation transcript:

1 1 6 5 4 3 2 Mg(s) + C l 2 (g) MgC l 2 (s) Mg(g) + C l 2 (g) Mg(g) + 2C l (g) Mg 2+ (g) + 2C l – (g) 7 Mg + (g) + 2C l (g) Mg 2+ (g) + 2C l (g) Enthalpy of formation of MgC l 2 Mg(s) + C l 2 (g) ——> MgC l 2 (s) Enthalpy of sublimation of magnesium Mg(s) ——> Mg(g) Enthalpy of atomisation of chlorine ½C l 2 (g) ——> C l (g) x2 Ist Ionisation Energy of magnesium Mg(g) ——> Mg + (g) + e¯ 2nd Ionisation Energy of magnesium Mg + (g) ——> Mg 2+ (g) + e¯ Electron Affinity of chlorine C l (g) + e¯ ——> C l ¯(g) x2 Lattice Enthalpy of MgC l 2 Mg 2+ (g) + 2C l ¯(g) ——> MgC l 2 (s) 1 2 3 4 5 7 6 Starter: write the corresponding equations for each enthalpy change.

2 Born-Haber cycle calculations L.O.:  Carry out calculations related to the Born-Haber cycle.

3 Cl¯ Br¯ F¯ O 2- Na + -780-742-918-2478 K + -711-679-817-2232 Rb + -685-656-783 Mg 2+ -2256-3791 Ca 2+ -2259 Lattice Enthalpy Values Smaller ions will have a greater attraction for each other because of their higher charge density. They will have larger Lattice Enthalpies and larger melting points because of the extra energy which must be put in to separate the oppositely charged ions. Units: kJ mol -1 Indentify the trend in the enthalpy values. Explain the reason for this trend.

4 C l ¯ Br¯ F¯ O 2- Na + -780-742-918-2478 K + -711-679-817-2232 Rb + -685-656-783 Mg 2+ -2256-3791 Ca 2+ -2259 Lattice Enthalpy Values Smaller ions will have a greater attraction for each other because of their higher charge density. They will have larger Lattice Enthalpies and larger melting points because of the extra energy which must be put in to separate the oppositely charged ions. Cl¯Cl¯ Na + Cl¯Cl¯ The sodium ion has the same charge as a potassium ion but is smaller. It has a higher charge density so will have a more effective attraction for the chloride ion. More energy will be released when they come together. K+K+

5 Task 1)Construct a Born-Haber cycle for sodium oxide. 2)Calculate the lattice enthalpy for sodium oxide  Ha(Na) = +108 KJ mol -1  Ha(O) = + 249 KJ mol -1  HI1 =+249 KJ mol -1  H EA1 = - 141 KJ mol -1  H EA2 = + 790 KJ mol -1  Hf(Na 2 O) = -414 KJ mol -1

6

Download ppt "1 6 5 4 3 2 Mg(s) + C l 2 (g) MgC l 2 (s) Mg(g) + C l 2 (g) Mg(g) + 2C l (g) Mg 2+ (g) + 2C l – (g) 7 Mg + (g) + 2C l (g) Mg 2+ (g) + 2C l (g) Enthalpy."

Similar presentations

A2 – CHEMICAL ENERGETICS

A2 – CHEMICAL ENERGETICS
BORN-HABER CYCLES A guide for A level students KNOCKHARDY PUBLISHING 2008 SPECIFICATIONS.

BORN-HABER CYCLES A guide for A level students KNOCKHARDY PUBLISHING 2008 SPECIFICATIONS.
Models of Chemical Bonding

Models of Chemical Bonding
CHEMISTRY DEPARTMENT WAID ACADEMY Trends in the Periodic Table.

CHEMISTRY DEPARTMENT WAID ACADEMY Trends in the Periodic Table.
15.2 Born-Haber Cycle 15.2.1 Define and apply the terms lattice enthalpy, and electron affinity 15.2.2 Explain how the relative sizes and the charges of.

15.2 Born-Haber Cycle Define and apply the terms lattice enthalpy, and electron affinity Explain how the relative sizes and the charges of.
Higher Chemistry Unit 1(c) Ionisation energy. After today’s lesson you should be able to: explain the meaning of the term ‘first ionisation energy’. write.

Higher Chemistry Unit 1(c) Ionisation energy. After today’s lesson you should be able to: explain the meaning of the term ‘first ionisation energy’. write.
Using Born Haber Cycles to Determine Lattice Enthalpies 15.2.3.

Using Born Haber Cycles to Determine Lattice Enthalpies
Enthalpy Change of formation is the enthalpy change when one mole of a compound is formed from its constituent elements under standard conditions. Enthalpy.

Enthalpy Change of formation is the enthalpy change when one mole of a compound is formed from its constituent elements under standard conditions. Enthalpy.
Title: Lesson 6 Born-Haber Cycles and Lattice Enthalpies Learning Objectives: – Understand the term lattice enthalpy – Use Born-Haber cycles to calculate.

Title: Lesson 6 Born-Haber Cycles and Lattice Enthalpies Learning Objectives: – Understand the term lattice enthalpy – Use Born-Haber cycles to calculate.
7 Ionic Bonding 7.1 Formation of Ionic Bonds: Donating and Accepting

7 Ionic Bonding 7.1 Formation of Ionic Bonds: Donating and Accepting
Chapter 7 Ionic Bonding 7.1 Ionic Bonds: Donating and Accepting Electrons 7.2 Energetics of Formation of Ionic Compounds 7.3 Stoichiometry of Ionic.

Chapter 7 Ionic Bonding 7.1 Ionic Bonds: Donating and Accepting Electrons 7.2 Energetics of Formation of Ionic Compounds 7.3 Stoichiometry of Ionic.
Chemical Bonding IONIC BONDS NOV. 21 Ionic Bonds  Characterized by a transfer of electrons  When electrons are transferred between atoms ions are produced.

Chemical Bonding IONIC BONDS NOV. 21 Ionic Bonds  Characterized by a transfer of electrons  When electrons are transferred between atoms ions are produced.
Ionic Bonding. CA Standards  Students know atoms combine to form molecules by sharing electrons to form covalent or metallic bonds or by exchanging electrons.

Ionic Bonding. CA Standards  Students know atoms combine to form molecules by sharing electrons to form covalent or metallic bonds or by exchanging electrons.
Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!

Ionic Bonding  Electrons are transferred  Electronegativity differences are generally greater than 1.7  The formation of ionic bonds is always exothermic!
Chapter 7 Summary  Here’s what you need to know Trends for and explanations of:  Electron Shells and Sizes of Atoms  Electronegativity  Ionization.

Chapter 7 Summary  Here’s what you need to know Trends for and explanations of:  Electron Shells and Sizes of Atoms  Electronegativity  Ionization.
Starter Give the electronic configuration of an atom of: - 9 4 Be - 24 12 Mg - 40 20 Ca Where are these elements found in the periodic table?

Starter Give the electronic configuration of an atom of: Be Mg Ca Where are these elements found in the periodic table?
For an ionic compound the lattice enthalpy is the heat energy released when one mole of solid in its standard state is formed from its ions in the gaseous.

For an ionic compound the lattice enthalpy is the heat energy released when one mole of solid in its standard state is formed from its ions in the gaseous.
CI 4.6 – Born-Haber Cycle (C) JHUDSON 2005. For an ionic compound the lattice enthalpy is the enthalpy change when one mole of solid in its standard state.

CI 4.6 – Born-Haber Cycle (C) JHUDSON For an ionic compound the lattice enthalpy is the enthalpy change when one mole of solid in its standard state.
Lattice Energy & the Born-Haber Cycle g.recall the stages involved in the formation of a solid ionic crystal from its elements and that this leads to a.

Lattice Energy & the Born-Haber Cycle g.recall the stages involved in the formation of a solid ionic crystal from its elements and that this leads to a.
Unit F321 Module 1.2.1 Electron Structure. Atomic Structure Protons, neutrons, electrons How to make ions Relative atomic mass.

Unit F321 Module Electron Structure. Atomic Structure Protons, neutrons, electrons How to make ions Relative atomic mass.

Similar presentations

Ads by Google